Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
~54864
_PCI~G..P~UND O~ THE IMVE,~1'rT~M
~ Field of the Invention
.~ 20 ~he ~resen-t invention relates ~Jenerally to
a color temperature control circuit for a color television
receiver, and is directed more particularl~t to a color
tem~erature control circuit for a color television receiver
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in which the blue primary color volta~e is made lar~e than
the red primar~ color voltage when the ratio between an outpu~
, by an input is nearer the white level more than ~ certain
: level.
Des_ription _f the_~rior ~.rt
In order to reproduce an ima~e on a color
television receiver with the complete color fidelity and
also beautiful white color at the white pea]c, it is necessary
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tha-t the reference ~7hite Oe the television receiver
(cathode ray tube~ is made 2ifferent hetween the time when
the luminance level of a video signal is low and the time
when the luminance level is hi~h. For exam~le, i-t is
desired that at a level lower than the flesh color level,
a color tem~erature is held at 9300K -~ 8 ~1PCD ~minimum
perceptible color difference~ while made at 14000K ~ 8MPCD
at the white ~eak level.
In the art there has been proposed an apparatus
to control the color temperature of a cathode ra~7 tube as
shown in Fig. 1. In this prior art control apparatus,
red, green and blue nri~ar~7 color signal voltages ~ G
and B derived from a color decoder lO are respectively
supplied througll a video output circuit 20 and throu~h
red, green and blue cathode resistors ~, PG and ~B to
control electrodes or cathodes ~R~ I~G and I~E of a tri-color
cathode ray tube 30. In this case, a series connectlon
of a zener diode ZG and a resistor rG is connected in parallel
to the green ca-thode resi.stor P~G and a ser:ies connection o
a zener diode ZB and a resistor rB is also connected in
parallel to the blue cathode resis-tor RB. Accordingl~,
~ when the green and blue cathode currents increase, the
`~ zener diodes ZG and %B ~ecome each conducted, and hence the
green and blue cathode feedhack resistances are reduced from
RG and RB ~ RG// rG and RB// rB respectlvelv. Thus, the
.
` green and l~lue feedback amounts decrease, and the green and
blue drive currents increase wherebv -the color tempera-ture
becornes higll.
In this case, however, the feedback resistance
is the sum of the output impedance of the video output
circuit 20 and the ahove resistance. Therefore, even if
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- the resis-tances are varied from RG and RB to RG // rG and
RB // rB/ the variation of the feedback resistance is less.
For this reason, t~he color temperature is less in variation
and hence it is rather difficult that a desired color tem-
perature is presented at a white peak level as indicated
by a solid line 1 in the graph of Fig. 2, and the color
temperature is insufficientasindicated hy a do-tted-line 2
in the graph of Fig. 2. If the feedback resistance is
varied at a lower luminance level to thereby vary the color
temperature, the desired color temperature can be obtained
`; at the white peak level as indicated by a dotted-line 3 in
the graph of Fig. 2. However, in order to repreduce the
color with high fidelity, it is necessary that the color
temperature IS kept at a low temperature until the flesh
~.olor level. Therefore, the above measure is not so
desired.
~nother meansure is also proposed, by which
the series connections of the zenoer diodes ZG' ZB and
resistors rG, rB shown in Fig. 1 are not used but the re-
sis-tance values of the cathode resistors RR, RG and RB
themselves are made different as RR? RG ~ RB. This
measure proposes the defect similar to the former measure.
In addition, it is not desired to select the resistance
values of the resistors RG, RB low in view of protecting
25 the video output circuit 20 from the discharge in the cathode
. ray tube 30. Further, when the differences among the
resistance values of -the resi.stors RR, RG, RB are large,
the frequency characteristics among the red, green and blue
primary colors do not coincide, the pulse characteristic is
deteriorated and a color smear is generated.
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~L~54864
O~J~.CTS AND ~u~ rY OD TIIE IN~)~NTION _
.ccordinalv, an object of the p~esent
invention i.s to provide a novel color temnerature control
circuit,for a color television receiver free Erom tl1e defect
encountered in the prior art.
Another object of the invention is to provide
a color temperature control circuit for a color television
receiver wllich can cor.trol the color temperature to be a
desired characteristic without the prior art defect.
~ccordin~ to an aspect of the present invention,
a color temperature control circuit for a color television
receiver is provided which comprises:
(A) a color decoder circuit supplied wi-th a composite
., video signal and for generating red, green and blue
primary color signals at its outputs;
(~) a video output circuit for amplif~ing said three
.' primary color signals;
(C) a -tri-color cathode ray tube havin~ three control elect-
rodes ada~ted to receive salcl tl1ree primary color si~nals
from saicl v;.deo output circuit; and
.': (D) a circuit arrangement connected between said color
decoder CirGUit and said video output circuit, said
circu.i.t arran~ement havin(3 the same transfer function
for all three primary color si~3nals when the innut signals
are below a predetermined level and havin~ transfer function
for the blue primary color si(3nal large than that for
the red primary color si~3nal when inpu-t si~nal levels
of said blue and red ~rimary color signals are larger
than saic1, ~rede-termined level,
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.~ The other objeets, ~eatuxes and ad,v,a,nta~es
of the presen-t invention will become a~parent ~rom the
following description taken in conjunction with the aeeompany-
' . ing drawings through which the like references designate :'
- 5 the same elements and parts.
BRIEF DESCRII'TION ()F THE D~AI7INGS
Fig. 1 is a connection cliagram showing partial-
ly, in block a prior art color tem~erature control apparatus
for use with a color television receiver;
Fi~. 2 is a ~raph used to explain the apparatus
shown in .Fig. l;
Fig. 3 is a s~rs-tematic diagram showing
partially i,n bloek the fundamental construction o. the eolor
temperature control circuit for a color television receiver
~,. 15 aecording to the present invention; ;~
. Fig. 4 is a connection diayram showing a
Practical exa~ple of the invention; and
~' Figs. 5 to 7 are respeetively yraphs showin~
the characteristics oE various eases of the invention.
DESCRIPTION OF THE PREFEP~RED EMBODI~.ENT
Fig. 3 shows the theoretical construction
of the color temperature control circuit for a color tele- ;
vision receiver aceordiny to the present invention in which
the references samc as those used in Fig. 1 designate the
same elements and ~arts. Aecording to the invention,
although the red, green and blue primary color signal vol-
tages R, G and B delivered from the color decoder 10 are
respectively supplied through the video out~ut circuit 20 and :~
.. , through the cathode resistors R ~ ~G and RB to the control
30 electrodes or cathodes K~, K~ and I~B of the tri-color ca-thode
-- 6
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ray tube 30, non-linear and linear circuits 40~ OG and
40B are respectively inserted between the color decoder 10
and the video output circuit 20.
i In this case, the circuit 40B which is inserted
into the blue primary color signal voltage line is a linear
circuit which is so formed that the ratio between its output
by its input becomes a constant value Go regardless of the
input level thereto as indicated bv a straight line 5~ in the
graph of Fig. 5; the circuit 40G which is lnserted into the
green primary color signal voltage line is a non-linear circuit
which is so formed that the ratio between its output and input
becomes Go when its input level is lo~er than a certain level
VO while becomes a value 5L lower than the value Go when the
input level is higher than VO as indicated by a bent line 5G
- 1~ in'the graph of ~ig. 5; and the circuit 40~. which is inserted
into the red prlmary color signal voltage line is also a non
.~ -linear circuit which is so formed that the ratio between its
output and inpu-t becomes Go when its input level is lower than
the level VO while becomes a value G~ lower tlan the value GL
wllen -the input level ls hiyher than V~ as indicated by a bent
line 5R in the graph of ~ig. 5.
,~ Accordingly, with the construction of the
inven-tion shown in Fig. 3, when t'ne red and green primary
;~ color signal voltages become bo-th higher than the level VO,
' the red and green primary color siynal volta~es are both
'~ compressed and hence the blue primar~,~ color signal voltage
is relatively expanded with the result that the blue drive
~' current increases to make the color tempera-ture high,
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Thus, by selecting the level VO, the color tem~erature of
93001~ ~ 8MPCn is kept in the range lower -than the flesh
color level, while by selecting the above values GL and GLL
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the color temperature of l~OOO~ 8 ~PCD can ~e presented
at the white ~ea]~ level.
In this case, the video output circuit 20 is
formed of an SEPP (single-ended push-pull) circuit and so
on and the output impedance thereof is selected as a low
impedance smaller than such as several hundred Q to pro-
vide a linear out~ut.
Fig. 4 shows a practical example of the
circuit construction shown in Fig. 3 in which 40 designates
generally the circuits 40P~, 40~ and 40B described above.
In the example of the invention shown in
Fig. 4, the red, green and blue primarv color signal voltages
; R, G and ~ delivered from the color decoder 10 are respectivel~
applied through resistors ~XR~ ~XG and RXB, the base-emitter
paths of transistors QR~ QG and ~B~ and through volumes
(variable resistors) RDP~ RDG and RDB for -the drive amount
; adjustment to the video output circuit 20. ~he bases of
the transistors O~ and ~ are connected -to~e-ther -througll a
series connection of a resistor RYR and a cliode DR and a
series connection of a resis-tor RyG and a diode DG to the emitter
of a transistor QO whose base is supplied with the voltage VO.
~ccordingly, with the example of the invention
shown in ~ig. 4, when the red and greèn primar~ color signal
; voltages R and C- become hi~her than the voltage or level VO,
the diodes DR and DG turn O~ hus, the red and green
-~ primary color signal voltaqes R and G are respectivelv com-
pressed at the ratios of YR and RYG
; ` ~R YR RXG + RyG
` so that the blue primary color signal voltage B is relatively
i expanded.
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In -the example of Fig. 4, the circuit for
the blue primary color signal voltage B is formed to be
a linear circuit with the characteristic as indicated by
a straight line 6B in the graph of Fig. 6, while the circuits
for the green and red primarv color signal voltages G and
are respectively formed to be non-linear circuits with such
characteristics that when the input levels thereto are
higher than the level V~, the ratios between their outputs
by the inputs thereof are chan~ed at plura]. stages to be
approximated in curve as indicated by bent lines 6G and 6
in the graph of Fi~. 6.
. If the circuit correspondiny to the transistor~ is provided plural, it may be possible to present the
above characteristics.
Further, -the circuit for the red primary color
, signal voltage is a linear circuit which is so formed that
; the ratio between its outut by its input becomes the constant
value Go regardless of the inpu-t level thereto as indicated
by a straight line 7~ in the ~raph oE Fiy. 7; the circuit
~'~ 20 for the cJreen primary color siynal voltage is a non-linear
.~ circuit which is so formed that the ra-tio be-tween its outnut
and inpu-t becomes Go when its input level is lower than the
~: level VO wnile becomes a value GH higher than the value Go
- when the input level is hi~her than VO as indicated b~ a
` 25 bent line 7G in the graph of Fi~. 7; and the circuit for
,~ the blue primary coIor signal voltage is also a non-linear
circuit which is so formed that -the ratio between its outpu-t
`~ and input becomes Go when its input level is lower than the
level VO while becomes a value GHH hiyher than the value
GH when the input level is hiqher than VO as indicated by
a bent line 7B in -the yraph of Fiy. 7.
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3L~5~L~3641
Sinee aceordlng to the invention in order
to increase the color te~perature high it is sufficient to
inerease the blue drive eurrent, it ma~l be enough that the
eireuit for the green primarv eolor sic~nal voltage is same
as that of the circuit or the red primartr color signal
voltage in charae-teristie !
As described above, accordina to the present
invention, the color temperature ean be controlled to be
of a desired eharaeteristie and it is needless to seleet
10 the resistanee values of the eathode resistors small, so
that no Problem is introdueed in vie~ of the eounter~easure
for the diseharge of the eolor eathode rat~ tube.
Further, aecording to the invention, due to
the fact that the cathode resistors can be seleeted equal in
~ 15 resistanee value, sueh a defeet can be avoided that the fre-
; quenev eharaeteristies can not be coincided among the red,
green and blue eolors and henee the pulse eharaeteristie is
deteriorated.
- It will be a~parent that many modi:Eieations
and variations eoulcl be effected by one skilled in -the art
,' without departing from the spiri-ts or scope of -the novel
. concepts oE the present invention so that the spirits or
';~ seope of the invention should be determined by the appended
,~ elaims only.
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